# Why do we need 'seq' or 'pseq' with 'par' in Haskell?

I'm trying to understand why we need all parts of the standard sample code:

``````a `par` b `pseq` a+b
``````

Why won't the following be sufficient?

``````a `par` b `par` a+b
``````

The above expression seems very descriptive: Try to evaluate both `a` and `b` in parallel, and return the result `a+b`. Is the reason only that of efficiency: the second version would spark off twice instead of once?

How about the following, more succinct version?

``````a `par` a+b
``````

Why would we need to make sure `b` is evaluated before `a+b` as in the original, standard code?

-

In summary, the problem with

``````a `par` b `par` a+b
``````

and

``````a `par` a+b
``````

is the lack of ordering of evaluation. In both versions, the main thread gets to work on `a` (or sometimes `b`) immediately, causing the sparks to "fizzle" away immediately since there is no more need to start a thread to evaluate what the main thread has already started evaluating.

The original version

``````a `par` b `pseq` a+b
``````

ensures the main thread works on `b` before `a+b` (or else would have started evaluating `a` instead), thus giving a chance for the spark `a` to materialize into a thread for parallel evaluation.

-
This is correct, and also explains why `seq` is insufficient for this problem. `seq` makes no guarantees about ordering of evaluation. In `seq b (a+b)`, the main thread may evaluate `a` before `b` so long as `b` is in WHNF when `(a+b)` is evaluated. –  John L Jan 2 '11 at 13:20
I don't see how that argument describes the problem with `par a (par b (a + b))` - sure, either `a` or `b` will immediately be evaluated, and the corresponding spark will fizzle, but the other spark should be very much alive, producing parallelism. Of course, creating then fizzling a spark might not be the most efficient way to do this, but it works and leaves the evaluation order question to the compiler. –  gereeter Oct 17 '12 at 3:48
``````a `par` b `par` a+b